JP2005353264A - Redundancy circuits of memory devices having twist bitline scheme and method of repairing defective cell - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a redundancy circuit of a memory apparatus having twist bitline scheme, and a method of repairing defective cells. <P>SOLUTION: This redundancy circuit includes a plurality of fuses and generates a repair address by programming a fuse to be made correspond to an address of a defective cell. A memory cell array block in the memory apparatus which is divided basing a twist bitline as reference is addressed in a block address. A word line coupled to the defective cell is replaced by a spare word line by a coding part responding to the block address selecting the memory cell array block in which the repair address and the defective cells are caused. Thereby, since the plurality of memory cell array blocks in which the twisted bitline is arranged share one redundancy circuit, the chip area of the memory apparatus is not extended. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a semiconductor memory device, and more particularly to a redundant circuit and a defective cell relief method for a memory device having a twisted bit line structure.

As the cell density of a semiconductor memory device, in particular, a DRAM is highly integrated, the bit line interval is narrowed. As a result, the bit line coupling noise increased rapidly during memory cell data sensing, and a twisted bit line structure was developed to solve this.
Twisted bit line structure consists of bit line BL and complementary bit line

Is a structure in which positions are replaced at regular intervals, and an arbitrary bit line BL and a complementary bit line are adjusted by appropriately adjusting the arrangement of odd and even columns.

The bit line coupling noises generated in the above are canceled out by canceling each other using the bit line coupling noises applied to the bit lines of the adjacent columns.

  When a defective cell is generated in a memory cell array having such a twist bit line structure, a repair technique is used to replace it with a spare cell (or a redundant cell). Thereby, the semiconductor production yield (yield) is improved. However, in the twisted bit line structure, since the bit line is twisted, the data scramble differs depending on the position of the memory cell connected to one word line.

  FIG. 1 is a diagram illustrating a data scrambled aspect during repair in a twisted bit line structure and a folded bit line structure. In FIG. 1, the first bit line and the complementary bit line BL0,

Has a twisted bit line structure, and a second bit line and a complementary bit line BL1,

Indicates a folded bit line structure. A first bit line and a complementary bit line BL0,

And the second bit line and the complementary bit line BL1,

Memory cells are arranged between the first to fourth word lines WL0 to WL3 which are cross-arranged. When the data pattern stored in the memory cell is “1”, it is indicated as T (True), and when it is “0”, it is indicated as C (Complement).

  It is assumed that the “TCCT” data pattern is stored in the memory cells connected to the first to fourth word lines WL0 to WL3 in the twist bit line structure. Since these memory cells are defective, if the first word line WL0 to the fourth word line WL3 are repaired to the first spare word line SWL0 to the fourth spare word line SWL3, the bit line is twisted. For this reason, it is shown that the “CTTC” data pattern is stored in the spare cells connected to the first to fourth spare word lines SWL0 to SWL3. Thus, after repairing a defective cell, in the test process that finally screens the defective cell, there is no data scramble information about the portion where the data scramble is different, or the defective cell is not screened, or There is a possibility that a normal cell is erroneously determined as a defective cell.

  On the other hand, in the folded bit line structure, since the memory cells connected to the first word line WL0 to the fourth word line WL3 are defective, they are transferred to the first spare word line SWL0 to the fourth spare word line SWL3. If the spare cell is repaired, the “TCCT” data pattern stored in the memory cell connected to the first word line WL0 to the fourth word line WL3 is transferred to the first spare word line SWL0 to the fourth spare word line SWL3. The connected spare cells are also shown as “TCCT” data patterns.

  Therefore, in order to repair a defective cell with a twisted bit line structure, for example, if there is one twisted point on the bit line with reference to the point where the bit line is twisted, a word in which defective cells are connected. Spare word lines for repairing a line (hereinafter referred to as “defective word line”) must be present at two locations on both sides with respect to the twisted point. As a result, data is stored in the spare cell connected to the spare word line in accordance with the data scramble of the defective cell as in the folded bit line structure.

However, in order to replace a defective word line with a spare word line based on the twist point in the twist bit line structure, an address fuse cutting unit for replacing the address corresponding to the defective word line with the address of the spare word line is provided. Each spare word line must be provided. Since the address fuse cutting part occupies a large layout area, there is a problem that the chip size of the memory device increases proportionally as the number of different data scrambles increases.
Therefore, there is a demand for a method that can flexibly maintain redundancy efficiency without increasing the chip area with a twisted bit line structure.

An object of the present invention is to provide a redundant circuit of a memory device having a twisted bit line structure.
Another object of the present invention is to provide a method for relieving a defective cell in a memory device having a twisted bit line structure.

  To achieve the above object, the present invention provides a redundant circuit for relieving a defective cell in a memory device having a twisted bit line structure, including a plurality of fuses, and programming the fuse to correspond to the address of the defective cell. A fuse section for generating a repair address, a block addressing section for generating a block address for addressing each memory cell array block in the memory device divided based on the twist bit line, and a memory in which a repair address and a defective cell are generated A coding unit for selecting a spare word line in response to a block address for selecting a cell array block.

  Preferably, the redundant circuit of the present invention is shared by the memory cell array blocks. The fuse unit is programmed by cutting or short-circuiting the fuse according to the address of the defective cell, and the coding unit is configured by a NAND gate that inputs a repair address and a block address. Spare word lines are arranged for each memory cell array block.

According to another aspect of the present invention, there is provided a method of relieving a defective cell in a memory device having a twisted bit line structure, and generating a repair address signal by programming a fuse according to an address of the defective cell. Of the memory cell array blocks in the memory device, which are divided according to a stage and a twist bit line. Generating a block address signal for selecting a memory cell array block in which a defective cell has occurred; selecting a spare word line in a memory cell array block in which a defective cell has occurred in response to a repair address signal and a block address signal; including.
More preferably, the method for relieving a defective cell having a twist bit line structure according to the present invention further includes a step of blocking an address line for selecting a defective cell.

  According to the present invention, since a plurality of memory cell array blocks in which twisted bit lines are arranged share one redundant circuit, the chip area of the memory device is not increased. In addition, one redundant circuit of the present invention maintains the same redundancy efficiency as that of a conventional redundant circuit provided for each memory cell array block divided on the basis of twisted bit lines.

For a full understanding of the invention, its operational advantages, and the objectives achieved by the practice of the invention, reference should be made to the accompanying drawings that illustrate preferred embodiments of the invention and the contents described in the accompanying drawings. I have to do it.
Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The same reference numerals provided in each drawing denote the same members.

  FIG. 2 illustrates a memory device having a first type twisted bit line structure sharing a redundant circuit according to the present invention. Referring to the memory device 200, the twisted bit lines are arranged over the first memory cell array block 210a and the second memory cell array block 210b. The first memory cell array block 210a and the second memory cell array block 210b are different in data scrambling because the bit lines are twisted. In order to relieve defective cells generated in the first and second memory cell array blocks 210a and 210b and to provide the spare cells with the same data scrambled data as the defective cells during the test, the first memory cell array block 210a The word line (not shown) connected to the defective cell generated in step 1 is replaced by the first spare word line SWLa disposed in the first memory cell array block 210a by the redundancy circuit 230, and generated in the second memory cell array block 210b. The word line (not shown) connected to the defective cell is replaced with the second spare word line SWLb arranged in the second memory cell array block (210b) by the redundancy circuit 230. As a result, the defective cell is replaced with a spare cell connected to the spare word line.

  The first type of twisted bit line structure includes a first bit line 212, a second bit line 214, a third bit line 216 and a fourth bit line in the first memory cell array block 210a in the twisted bit line unit array 210. In the second memory cell array block 201b, the arrangement 218 is arranged in the order of the third bit line 216-first bit line 212-fourth bit line 218-second bit line 214. The second bit line 214 and the third bit line 216 are connected to the first bit line sense amplifier 220a on the first memory cell array block 210a side, and the first bit line 212 and the fourth bit line 218 are connected to the second memory. The second bit line sense amplifier 220b on the cell array 210b side is connected. The first bit line sense amplifier 220a senses and amplifies the voltage difference between the second bit line 214 and the third bit line 216, and the second bit line sense amplifier 220b includes the first bit line 212 and the fourth bit line 218. Senses and amplifies the voltage difference.

  The redundancy circuit 230 includes a fuse unit 232, first and second block addressing units 234 and 236, and first and second coding units 238 and 239. The first and second block addressing units 234 and 236 provide block addresses for selecting the first and second memory cell array blocks 210a and 210b to the first and second coding units 238 and 239, respectively. The fuse unit 232 includes a plurality of fuses connected to address signal lines, and the fuses are short-circuited or cut to correspond to an address for selecting a word line of a defective cell in the first or second memory cell array blocks 210a and 210b. Then, the repair address is provided to the first and second coding units 238 and 239. The first and second coding units 238 and 239 select the first and second spare word lines SWEa and SWEb in response to the repair address and the outputs of the first and second block addressing units 234 and 236, respectively. .

  The first spare word line SWLa is selected in place of the defective word line when a word line connected to defective cells generated in the first memory cell array block 210a is selected. The second spare word line SWLb is selected in place of the defective word line when the word line connected to the defective cells generated in the second memory cell array block 210b is selected. At this time, the output line of the address decoder connected to the defective word line is cut off.

  Therefore, the redundancy circuit 230 of this embodiment is shared by the first memory cell array block 210a and the second memory cell array block 210b, and the first or second block addressing unit 234 for selecting the memory cell array block in which the defective cell is generated. The first or second spare word line SWLa, SWLb is selectively selected by the output of 236. As a result, the same data scramble as the data pattern applied to the defective cell during the test is reproduced as it is in the spare cell connected to the first or second spare word line SWLa, SWLb. As a result, the shared redundant circuit 230 does not increase the chip area of the memory device. In addition, the redundancy efficiency of the redundancy circuit that had to be provided on both sides with respect to the conventional twisted bit line is kept the same.

  FIG. 3 illustrates a memory device having a second type twisted bit line structure sharing a redundant circuit according to the present invention. Referring to FIG. 2, the memory device 300 includes a word line in which defective cells in the first or second memory cell array blocks 310a and 310b having the second type twist bit line structure are connected by the redundancy circuit 230 described with reference to FIG. Is selectively replaced with the first or second spare word line SWLa, SWLb according to the output of the first or second block addressing unit 234, 236.

  The second type twisted bit line structure includes a first bit line 312-a second bit line 314-a third bit line 316-a fourth bit line in the first memory cell array block 310 a in the twisted bit line unit array 310. In the second memory cell array block 301b, the arrangement of 318 is arranged in the order of the first bit line 312—the third bit line 316—the second bit line 314—the fourth bit line 318. The second bit line 314 and the third bit line 316 are connected to the bit line sense amplifier 320a on the first memory cell array block 310a side, and the first bit line 312 and the fourth bit line 318 are connected to the second memory cell array 310b. Side bit line sense amplifier 320b. The first bit line sense amplifier 320a senses and amplifies the voltage difference between the second bit line 314 and the third bit line 316, and the second bit line sense amplifier 320b includes the first bit line 312 and the fourth bit line 318. Senses and amplifies the voltage difference.

  FIG. 4 is a diagram illustrating a memory device having a third type twisted bit line structure sharing a redundant circuit according to the present invention. Referring to FIG. 2, the memory device 400 includes a word line in which defective cells in the first or second memory cell array blocks 410a and 410b having the third type twist bit line structure are connected by the redundancy circuit 230 described with reference to FIG. Is selectively replaced with the first or second spare word line SWLa, SWLb according to the output of the first or second block addressing unit 234, 236.

  The third type of twisted bit line structure includes a first bit line 412 to a second bit line 414 to a third bit line 416 to a fourth bit in the first memory cell array block 410a in a unit array 410 such as a twisted bit line. In the second memory cell array block 401b, the lines 418 are arranged in the order of the first bit line 412—the third bit line 416—the fourth bit line 418—the second bit line 414. The second bit line 414 and the third bit line 416 are connected to the bit line sense amplifier 420a on the first memory cell array block 410a side, and the first bit line 412 and the fourth bit line 418 are connected to the second memory cell array 410b. Side bit line sense amplifier 420b. The first bit line sense amplifier 420a senses and amplifies the voltage difference between the second bit line 414 and the third bit line 416, and the second bit line sense amplifier 420b includes the first bit line 412 and the fourth bit line 418. Senses and amplifies the voltage difference.

  FIG. 5 illustrates a memory device having a fourth type twisted bit line structure sharing a redundant circuit according to the present invention. Referring to FIG. 2, the memory device 500 uses the redundancy circuit 230 described with reference to FIG. 2 to detect defective cells in the first or second memory cell array blocks 510a and 510b having the fourth type twist bit line structure including dummy bit lines. Are connected to the first or second spare word lines SWLa and SWLb selectively according to the outputs of the first or second block addressing units 234 and 236.

  FIG. 6 is a diagram illustrating a memory device having a fifth type twisted bit line structure sharing a redundant circuit according to the present invention. Referring to this, in the memory device 600, the fifth type twist bit lines are arranged over the memory cell array blocks 610a, 610b, 610c, and 610d. The fifth type twisted bit line structure is a twisted bit line unit array 610 in which the first and third bit lines 612 and 616 are twisted once between the first memory cell array block 610a and the second memory cell array block 610b. The second and fourth bit lines 614 and 618 are twisted once more between the third memory cell array block 610c and the fourth memory cell array block 610d, and the second and fourth bit lines 614 and 618 are connected to the second memory cell array block 610b and the third memory cell array 610b. Twisted with the cell array block 610c once. Accordingly, the first to fourth memory cell array blocks 610a, 610b, 610c, and 610d have different data scrambles due to the twisted bit lines.

  In order to relieve defective cells generated in the first to fourth memory cell array blocks 610a, 610b, 610b, and 610d, and to have the same data scramble as the data scramble of the defective cells during the test, the redundant circuit 630 A word line (not shown) connected to a defective cell generated in one memory cell array block 610a is replaced with a first spare word line SWLa arranged in the first memory cell array block 610a, and a second memory cell array block 610b. A word line (not shown) connected to the generated defective cell is replaced with a second spare word line SWLb arranged in the second memory cell array block 610b. A word line (not shown) connected to a defective cell generated in the third memory cell array block 610c is replaced with a third spare word line SWLc disposed in the third memory cell array block 610c, and the fourth memory cell array A word line (not shown) connected to the defective cell generated in the block 610d is replaced with a fourth spare word line SWLd arranged in the fourth memory cell array block 610d. Accordingly, the defective cells of the first to fourth memory cell array blocks 610a, 610b, 610b, and 610d are replaced with spare cells connected to the spare word lines SWLa, SWLb, SWLc, and SWLd.

  The redundancy circuit 630 includes a fuse part 631, first to fourth block addressing parts 632, 633, 634, 635, and first to fourth coding parts 636, 637, 638, 639. The first to fourth block addressing units 632, 633, 634, and 635 receive block addresses for selecting the first to fourth memory cell array blocks 610a, 610b, 610c, and 610d as the first to fourth coding units 636, 637, respectively. 638, 639.

  The fuse unit 631 includes a plurality of fuses connected to the address signal lines, and corresponds to an address for selecting a word line of a defective cell in the first or fourth memory cell array block 610a, 610b, 610c, 610d. And the repair address is provided to the first to fourth coding units 636, 637, 638, and 639. The first through fourth coding units 636, 637, 638, and 639 are responsive to the repair address and the outputs of the first through fourth block addressing units 632, 633, 634, and 635, respectively. Lines SWLa, SWLb, SWLc, and SWLd are selected.

  As a result, the same data scramble as the data pattern applied to the defective cell during the test is reproduced as it is in the spare cell connected to the first to fourth spare word lines SWLa, SWLb, SWLc, SWLd. Accordingly, one shared redundant circuit 630 does not increase the chip area of the memory device, and is provided for each of the first to fourth memory cell array blocks 610a, 610b, 610c, and 610d based on a conventional twisted bit line. The redundancy efficiency of the redundant circuit that had to be maintained is kept the same.

  Although the present invention has been described with reference to one embodiment shown in the drawings, it is intended to be exemplary only, and various modifications and equivalent other embodiments may be made by those skilled in the art. I understand that. Therefore, the true technical protection scope of the present invention must be determined by the technical ideas of the claims.

  The present invention can be suitably applied to a technical field related to a memory device having a twisted bit line structure.

6 is a diagram for explaining data scrambling during repair in a twisted bit line structure and a folded bit line structure. 1 is a diagram illustrating a memory device having a first type twist bit line structure sharing a redundant circuit according to the present invention; 3 is a diagram illustrating a memory device having a second type twisted bit line structure sharing a redundant circuit according to the present invention; 3 is a diagram illustrating a memory device having a third type twisted bit line structure sharing a redundant circuit according to the present invention; 4 is a diagram illustrating a memory device having a fourth type twisted bit line structure sharing a redundant circuit according to the present invention. 6 is a diagram illustrating a memory device having a fifth type twisted bit line structure sharing a redundant circuit according to the present invention;

Explanation of symbols

200 memory device 210 twist bit line unit array 210a first memory cell array block 210b second memory cell array block 212 first bit line 214 second bit line 216 third bit line 218 fourth bit line 220a first bit line sense amplifier 220b Second bit line sense amplifier 230 Redundant circuit 232 Fuse unit 234 First block addressing unit 236 Second block addressing unit 238 First coding unit 239 Second coding unit SWLa First spare word line SWLb Second spare word line

Claims (18)

In a redundant circuit for an integrated circuit memory device,
The redundant circuit is:
A first memory cell block including a plurality of main word lines and a spare word line respectively connected to the plurality of memory cells;
A second memory cell block including a plurality of main word lines and a spare word line respectively connected to the plurality of memory cells;
The first and second memory cell blocks are arranged over the entire area, a bit line is twisted between the first memory cell block and the second memory cell block, and the twist is formed in the first and second memory cell blocks. A plurality of bit lines having a bit line structure that is not
One of the main word lines of the first memory cell block connected to all the main word lines and the spare word lines of the first and second memory cell blocks and connected to the first defective cell. For the replacement, the spare word line of the first memory cell block is selected, and the first word line of the second memory cell block connected to the second defective cell is replaced with the first word line. The spare word line of the two memory cell blocks is selected, and the data stored in the spare cell connected to the selected spare word line is the same data as the cell connected to one of the replaced main word lines. A redundant circuit having scrambling. The integrated circuit memory device including the redundant circuit includes:
A first memory cell block including a plurality of main word lines and a spare word line respectively connected to the plurality of memory cells;
A second memory cell block including a plurality of main word lines and a spare word line respectively connected to the plurality of memory cells;
The first and second memory cell blocks are arranged over the entire area, a bit line is twisted between the first memory cell block and the second memory cell block, and the twist is formed in the first and second memory cell blocks. The redundant circuit according to claim 1, further comprising a plurality of bit lines having a bit line structure that is not performed. The redundant circuit is:
A first block address unit for generating an address associated with the first memory cell block;
A second block address unit for generating an address associated with the second memory cell block;
A program unit for generating a repair address associated with a spare word line for replacing a defective cell;
In order to replace one of the main word lines of the first memory cell block associated with a defective cell corresponding to the repair address of the program unit and the address of the first block address unit, the first memory One of the main word lines of the second memory cell block associated with a defective cell corresponding to the repair address of the program unit and the address of the second block address unit is selected from the spare word line of the cell block. The redundancy circuit according to claim 1, further comprising: a coding unit that selects the spare word line of the second memory cell block to replace one of the second memory cell blocks.   4. The redundant circuit according to claim 3, wherein the first and second memory cell blocks include a plurality of spare word lines. The integrated circuit device includes:
At least three memory cell blocks;
The plurality of bit lines that are arranged over the entire area of the at least three memory cell blocks, the bit lines are twisted in adjacent regions of the at least three memory cell blocks, and are not twisted in the respective memory cell blocks; With
The redundancy circuit is connected to each of the at least three memory cell blocks, and replaces one of the main word lines among at least three memory cell blocks connected to a defective cell. Of the at least three memory cell blocks, the spare word line of the corresponding memory cell block is selected, and the data stored in the spare cell connected to the selected spare word line is the main word line to be replaced. The redundant circuit according to claim 4, wherein the redundant circuit has the same data scrambling as a cell connected to one cell. The program part
The redundant circuit according to claim 3, further comprising a fuse unit including a plurality of fuses configured to be programmed to generate the repair address. The fuse portion is
The redundant circuit according to claim 6, wherein the fuse is programmed by short-circuiting or cutting the fuse according to an address of a defective cell. The coding part is
A first NAND gate connected to the first memory cell block and receiving the repair address and an address from the first block addressing unit;
4. The redundancy circuit of claim 3, further comprising: a second NAND gate connected to the second memory cell block and receiving the repair address and an address from the second block addressing unit. The redundant circuit is:
4. The redundant circuit according to claim 3, wherein an address line for selecting the defective cell is cut off. In a redundant circuit for relieving a defective cell in a memory device having a twisted bit line structure,
A fuse unit including a plurality of fuses, and generating a repair address by programming the fuse to correspond to the address of the defective cell;
A block addressing unit for generating a block address for addressing each memory cell array block of the memory device that is divided based on the twist bit line;
A redundancy circuit comprising: a coding unit for selecting a spare word line in response to the block address for selecting the memory cell array block in which the repair address and the defective cell are generated. The redundant circuit is:
The redundant circuit according to claim 10, wherein the redundant circuit is shared by the memory cell array block. The fuse portion is
11. The redundancy circuit according to claim 10, wherein the programming is performed by cutting or short-circuiting the fuse according to an address of the defective cell. The coding part is
The redundant circuit according to claim 10, comprising a NAND gate that inputs each of the repair address and the block address. The redundant circuit is:
11. The redundancy circuit according to claim 10, wherein an address line for selecting the defective cell is cut off.   11. The redundancy circuit according to claim 10, wherein the spare word line is arranged for each memory cell array block. In a method for relieving a defective cell of a memory device having a twisted bit line structure,
Programming a fuse to correspond to the address of the defective cell to generate a repair address;
Generating a block address signal for selecting the memory cell array block in which the defective cell is generated out of the memory cell array blocks of the memory device divided based on the twist bit line;
Selecting a spare word line in the memory cell array block in which the defective cell is generated in response to the repair address and the block address, and a method of relieving a defective cell having a twist bit line structure. .   The method of claim 16, further comprising the step of blocking an address line for selecting the defective cell. . Programming the fuse comprises:
17. The method of claim 16, wherein the fuse is cut or short-circuited according to an address of the defective cell.

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